KR102610100B1 - tire - Google Patents

Abstract

One aspect of the tire 10 of the present invention is a tire including a tread portion 11, a side wall portion 12, and a bead portion 13, and a bead core 60 provided in the bead portion 13. and at least one carcass ply 51 along at least a portion around the core axis of the bead core 60, and a conductive rubber portion 80 provided between the carcass ply 51 and the bead core 60. It is provided, and the conductive rubber portion 80 conducts conduction between one surface and the other surface of at least one carcass ply 51.

Description

tire

The present invention relates to tires.

This application claims priority based on Japanese Patent Application No. 2019-115377, filed in Japan on June 21, 2019, the contents of which are incorporated herein by reference.

For example, as described in Patent Document 1, a tire provided with a carcass ply is known.

Japanese Patent Publication No. 2015-20499

For tires such as those described above, reduction of rolling resistance is required. In order to reduce rolling resistance, for example, the amount of carbon contained in the carcass rubber in the carcass ply can be reduced. However, if the amount of carbon contained in the carcass rubber is reduced, the volume specific resistance of the carcass rubber increases, and there is a possibility that the conductive path from the bead portion to the tread tread portion is blocked by the carcass ply. Therefore, there was a possibility that it would be difficult to discharge static electricity transmitted from the vehicle to the bead portion from the tread tread portion to the ground.

One aspect of the present invention, in light of the above-mentioned circumstances, has as one object the provision of a tire having a structure that facilitates dissipation of static electricity from a vehicle to the ground, regardless of the conductivity of the carcass ply.

One aspect of the tire of the present invention is a tire having a tread portion, a side wall portion, and a bead portion, including a bead core provided in the bead portion and at least one sheet along at least a portion around the core axis of the bead core. It has a carcass ply and a conductive rubber portion provided between the carcass ply and the bead core, wherein the conductive rubber portion causes one surface and the other surface of the at least one carcass ply to conduct electricity.

According to one aspect of the present invention, a tire is provided that has a structure that facilitates dissipation of static electricity from a vehicle to the ground, regardless of the conductivity of the carcass ply.

1 is a cross-sectional view schematically showing a part of the tire of this embodiment, and is a cross-sectional view along the tire width direction.
FIG. 2 is a cross-sectional view schematically showing a part of the tire of this embodiment, and is a partial enlarged view of FIG. 1.
FIG. 3 is a cross-sectional view schematically showing a part of the tire of this embodiment, and is a cross-sectional view taken along line III-III in FIG. 2.

Hereinafter, a tire according to an embodiment of the present invention will be described with reference to the drawings. In addition, the scope of the present invention is not limited to the following embodiments, and may be arbitrarily changed within the scope of the technical idea of the present invention. In addition, in the drawings below, in order to make each structure easier to understand, the scale and numbers of each structure may be different from those of the actual structure.

The Z-axis direction shown in each figure is a direction parallel to the tire diameter direction centered on the rotation axis of the tire 10. In each drawing, the tire diameter direction is the vertical direction. In a portion of the tire 10 shown in each drawing, the positive side in the Z-axis direction, i.e., the upper side in each drawing, is the outside of the tire radial direction, and the minus side in the Z-axis direction, i.e., the lower side in each drawing, is the tire radial direction. It's inside.

The Y-axis direction shown in each figure is a direction parallel to the tire width direction. In FIGS. 1 and 2, the tire width direction is left and right. In the following description, for an object, the side closest to the tire equator (CL) in the tire width direction is referred to as the "inside of the tire width direction", and the side closer to the tire equator (CL) in the tire width direction is referred to as the "inner side of the tire width direction". The far side is defined as “the outside of the tire width direction.” The tire equator CL is the center of the tire width direction in the tire 10 of this embodiment. In a portion of the tire 10 shown in each figure, the minus side in the Y-axis direction, i.e., for example, the right side in FIGS. 1 and 2, is the inside of the tire width direction, and the plus side in the Y-axis direction, i.e., for example, is the inside of the tire width direction. The left side of FIGS. 1 and 2 is the outer side of the tire width direction.

Additionally, the circumferential direction around the central axis of the tire 10 (not shown) is defined as the tire circumferential direction. The

In FIG. 1, among the cross sections of the tire 10 in the tire circumferential direction, only the portion located on one side in the tire width direction from the tire equator CL is shown. Among the cross sections of a portion of the tire 10 in the tire circumferential direction, the portion located on the other side of the tire width direction from the tire equator CL is between the portion shown in FIG. 1 and the tire equator CL. They are arranged symmetrically in the direction of the tire width. In the following description, the portion shown in FIG. 1 of the tire 10 will be described, and the description of the portion of the tire 10 located on the other side of the tire width direction from the tire equator CL will be omitted. There is.

As shown in FIG. 1, the tire 10 of this embodiment is provided with a tread portion 11, a side wall portion 12, and a bead portion 13.

The tread portion 11 is disposed outside the bead portion 13 in the tire radial direction, and is located at the outer end of the tire 10 in the tire radial direction. The tread portion 11 is annular extending along the direction around the tire. The tread portion 11 has a tread tread portion 11a, which is the contact surface of the tire 10. The tread tread portion 11a is a part of the outer surface of the tread portion 11 in the tire diameter direction.

The tread tread portion 11a is, for example, mounted on a tire 10 to a standard rim specified in the “JATMA Year Book,” and the tire 10 is provided with the applicable size and ply rating in the “JATMA Year Book.” The maximum load corresponding to the maximum load capacity is charged with an internal pressure (hereinafter referred to as the specified internal pressure) of 100% of the air pressure (maximum air pressure) corresponding to the maximum load capacity (load in bold letters in the internal pressure-load capacity correspondence table). This is the ground plane of the tread portion 11 in a loaded state.

In addition, for example, when the region where the tire 10 is produced or used is other than Japan, the tread tread portion 11a complies with the industrial standard applied in that region (for example, the "TRA Year Book of the United States of America") ”, European “ETRTO Standard Manual”, etc.) is the ground surface of the tread portion 11.

The side wall portion 12 extends from the outer end of the tread portion 11 in the tire width direction toward the inner side in the tire radial direction. The side wall portion 12 connects the outer end of the tread portion 11 in the tire width direction and the bead portion 13.

The bead portion 13 is connected to the inner end of the side wall portion 12 in the tire radial direction. A bead core 60 is provided in the bead portion 13. More specifically, a bead core 60 is embedded in the bead portion 13.

The tire 10 is provided with a carcass layer 50 that serves as a skeleton. The tire 10 is constructed by, for example, assembling the first chafer portion 71, the tire body 20, the belt layer 30, and the belt reinforcement layer 40 on the carcass layer 50. The carcass layer 50 is provided over the tread portion 11, the side wall portion 12, and the bead portion 13. The carcass layer 50 is annular extending along the direction around the tire. As shown in FIGS. 1 and 2, the carcass layer 50 has carcass plies 51 and conductive portions 52.

The carcass ply 51 covers at least a portion around the core axis of the bead core 60. In this embodiment, the carcass ply 51 extends from the tread portion 11 through the side wall portion 12 to the bead portion 13 and is bent outward in the tire width direction around the bead core 60. . The carcass ply 51 is an annular shape extending along the direction around the tire. As shown in FIG. 3, the carcass ply 51 has a carcass rubber 51a and a plurality of ply cords 51b. The carcass ply 51 is composed of a plurality of ply cords 51b embedded in the carcass rubber 51a.

In addition, in the following description, the inner surface of the surfaces of the carcass ply 51 is referred to as “one side surface”, and the outer surface of the surfaces of the carcass ply 51 is defined as “the other surface”. . One surface is a surface of the carcass ply 51 that is inside the tread portion 11 in the tire radial direction. The other side surface is the surface of the carcass ply 51 that is outside the tread portion 11 in the tire radial direction.

In this embodiment, the loss tangent tan δ of the carcass rubber 51a is relatively small. The loss tangent tanδ becomes smaller as the carbon content contained in the carcass rubber 51a decreases. The smaller the loss tangent tan δ of the carcass rubber 51a, the smaller the rolling resistance of the tire 10. In this embodiment, the carcass rubber 51a is relatively difficult to pass electricity through. As a result, the conductivity of the carcass ply 51 in this embodiment is relatively low.

The plurality of ply cords 51b, while embedded in the carcass rubber 51a, extend from the tread portion 11 through the side wall portion 12 to the bead portion 13 to form a tire around the bead core 60. It is bent outward in the width direction. The plurality of ply cords 51b are arranged at intervals along the tire circumferential direction. The fly cord 51b is, for example, an organic fiber cord.

The conductive portion 52 is provided on the outer surface of the carcass ply 51, that is, on the other side surface. As shown in FIG. 1, the conductive portion 52 extends along the carcass ply 51. The conductive portion 52 is located outside the carcass ply 51 in the tire diameter direction in the tread portion 11. In this embodiment, the conductive portion 52 extends from the tread portion 11 to at least the inside of the bead core 60 in the tire diameter direction. In this embodiment, the conductive portion 52 extends from the tread portion 11 through the side wall portion 12 to the bead portion 13 and is bent outward in the tire width direction around the bead core 60, and It extends to the outside of the bead core 60 in the tire width direction.

The outer end in the tire diameter direction of the portion of the conductive portion 52 bent around the bead core 60 is the outer end in the tire diameter direction of the portion of the carcass ply 51 bent around the bead core 60. They are arranged at the same position in the tire diameter direction. At least a portion of the conductive portion 52 is located between the carcass ply 51 and the bead core 60. In this embodiment, the conductive portion 52 has a portion located inside the bead core 60 in the tire diameter direction and a portion located on both sides of the bead core 60 in the tire width direction, and is a carcass ply ( It is located between 51) and the bead core 60. In this embodiment, the conductive portion 52 is connected to a conductive rubber portion 80 described later. As shown in FIG. 3, the plurality of conductive portions 52 are attached to the inner side of the bead core 60 in the tire radial direction and to the outer surface of the carcass rubber 51a in the tire radial direction.

In this embodiment, the conductive portion 52 is a filamentous member containing metal. The conductive portion 52 is, for example, a conductive thread in which metal fibers such as stainless steel are wound around organic fibers. A plurality of conductive portions 52 are provided at intervals along the tire circumferential direction.

3 shows, as an example, a state in which the plurality of conductive portions 52 are located outside the plurality of ply cords 51b in the tire radial direction, but the present invention is not limited to this. The positional relationship between the plurality of conductive portions 52 and the plurality of ply cords 51b in the tire circumferential direction is not particularly limited. That is, in FIG. 3, the left-right position of the conductive portion 52 may be shifted from the left-right position of the ply cord 51b. Additionally, the number of conductive portions 52 and the number of ply cords 51b may be the same or different.

The conductive portion 52 has conductivity. The volume resistivity of the conductive portion 52 is smaller than that of the conductive rubber portion described later. In addition, in this specification, "a member has conductivity" and "a member is relatively easy to pass electricity through" mean that the volume resistivity of the member is low enough to allow static electricity from the vehicle to flow.

The first chafer portion 71 has conductivity. The first chafer portion 71 is a rubber member or a composite member of fiber and rubber. As shown in FIG. 2, the first chafer portion 71 covers the portion provided in the bead portion 13 of the carcass ply 51 from the inner side in the tire diameter direction and both sides in the tire width direction. The portion of the carcass ply 51 provided in the bead portion 13 includes a portion of the carcass ply 51 that covers the bead core 60 from the inside in the tire diameter direction and from both sides in the tire width direction. In the following description, the portion of the carcass ply 51 provided in the bead portion 13 is defined as the core covering portion 53. The core covering portion 53 extends from the inside of the bead core 60 in the tire width direction, through the inside of the bead core 60 in the tire diameter direction, to the outside of the bead core 60 in the tire width direction. The first chafer portion 71 is annular extending along the tire circumferential direction.

The first chafer portion 71 has a radial direction covering portion 72 and a width direction covering portions 73 and 74. The radial coating portion 72 is a portion that covers the core coating portion 53 of the carcass ply 51 from the inside of the tire in the radial direction. The radial coating portion 72 extends in the tire width direction. The width direction coating portions 73 and 74 are portions that cover the core coating portion 53 of the carcass ply 51 from both sides in the tire width direction. The width direction coating portion 73 extends outward in the tire radial direction from the outer end of the radial direction coating portion 72 in the tire width direction, and covers the core coating portion 53 from the outside in the tire width direction. The width direction coating portion 74 extends from the inner end in the tire width direction of the radial direction coating portion 72 outward in the tire radial direction, and covers the core coating portion 53 from the inside in the tire width direction. The outer ends of the width direction coating portions 73 and 74 in the tire radial direction are inside the tire radial direction than the outer ends of the tire radial direction in the portion of the carcass ply 51 that is bent around the bead core 60. It is located in

As shown in FIG. 1, the tire body 20 has a tread rubber 21 and a side wall rubber 22.

The tread rubber 21 is a part that forms part of the tread portion 11 and is annular extending along the tire circumferential direction. The tread rubber 21 is provided on the outer side of the carcass layer 50 in the tire diameter direction. The tread rubber 21 is connected to the carcass layer 50 through the belt layer 30 and the belt reinforcement layer 40. In addition, in Figure 1, in order to schematically represent each part for easy understanding, the carcass layer 50, the tread rubber 21, the belt layer 30, and the belt reinforcement layer 40 are shown spaced apart. there is.

The tread rubber 21 has a tread under cushion 23, a base layer 24, a cap layer 25, a mini side 26, and an antenna rubber 27.

The tread under cushion 23, base layer 24, and cap layer 25 are stacked in this order from the inside of the tire in the diametric direction to the outside of the tire in the diametric direction. The outer surface of the cap layer 25 in the tire diameter direction constitutes the tread tread portion 11a. The mini side 26 is connected to the outer end of the stacked tread under cushion 23, base layer 24, and cap layer 25 in the tire width direction.

The antenna rubber 27 is embedded across the base layer 24 and the cap layer 25. The antenna rubber 27 penetrates the base layer 24 and the cap layer 25 in the tire diameter direction. The inner end of the antenna rubber 27 in the tire radial direction is connected to the outer surface of the tread under cushion 23 in the tire radial direction. The outer end of the antenna rubber 27 in the tire radial direction is exposed to the tire radial outer surface of the cap layer 25 and forms a part of the tread tread 11a. The antenna rubber 27 may extend intermittently in the direction around the tire, may extend continuously, or may be scattered.

The base layer 24, cap layer 25, and mini side 26 are relatively difficult to pass electricity through and have low conductivity. The tread under cushion 23 and the antenna rubber 27 relatively easily transmit electricity and are conductive.

The side wall rubber 22 is a part that constitutes a part of the side wall part 12 and a part of the bead part 13, and is annular extending along the tire circumferential direction. The side wall rubber 22 is provided on the outside of the carcass layer 50 in the tire width direction. The side wall rubber 22 is connected to the carcass layer 50. The outer end of the side wall rubber 22 in the tire diameter direction is connected to the outer end of the tread rubber 21 in the tire width direction. In addition, in FIG. 1, in order to schematically represent each part for easy understanding, the space between the side wall rubber 22 and the carcass layer 50 and between the side wall rubber 22 and the tread rubber 21 are shown. I'm doing it.

The side wall rubber 22 has a side wall rubber body portion 28 and a second chaper portion 29.

The side wall rubber body portion 28 is a part that forms part of the side wall portion 12. The outer end of the side wall rubber body portion 28 in the tire diameter direction extends inward in the tire width direction, and includes a carcass layer 50, a tread rubber 21, a belt layer 30, and a belt reinforcement layer ( 40) is located in between.

The second chafer portion 29 is a part that forms part of the bead portion 13. The second chafer portion 29 is connected to the inner end of the side wall rubber body portion 28 in the tire diameter direction. The second chafer portion 29 covers the core covering portion 53 in the carcass layer 50 from the outside in the tire width direction. The second chafer portion 29 is connected to the core coating portion 53 and the width direction coating portion 73 of the first chafer portion 71 from the outside in the tire width direction. In addition, in FIGS. 1 and 2, in order to schematically represent each part for easy understanding, a diagram is drawn between the second chafer part 29 and the core covering part 53 and between the second chafer part 29 and the width direction covering part ( 73) They are shown spaced apart.

The rubber material constituting the side wall rubber body portion 28 and the rubber material constituting the second chafer portion 29 have different volume specific resistances. The side wall rubber body portion 28 is relatively difficult to pass electricity through. The second chafer portion 29 relatively easily passes electricity and has conductivity.

In this embodiment, the above-described first chafer portion 71 and second chafer portion 29 constitute the chafer portion 70. That is, in this embodiment, the tire 10 has a chafer portion 70 that covers at least a part of the periphery of the carcass ply 51. In this embodiment, the chafer portion 70 covers at least the inner side of the core covering portion 53 in the tire diameter direction and the outer side in the tire width direction. The chafer portion 70 has conductivity. In the chafer portion 70, the volume resistivity of the first chafer portion 71 and the volume resistivity of the second chafer portion 29 may be the same or different from each other. In this embodiment, the chafer portion 70 covers the inner side of the core coating portion 53 in the tire diameter direction and both sides of the tire width direction, and is connected to the core coating portion 53. The chafer portion 70 is a portion that protects the carcass layer 50 from friction with the rim on which the tire 10 is installed.

The belt layer 30 is embedded in the tread portion 11. The belt layer 30 is laminated on the outer side of the carcass layer 50 in the tire diameter direction. The belt layer 30 is connected to the carcass ply 51 and the conductive portion 52. The belt layer 30 is located between the tread rubber 21 and the carcass layer 50 in the tire diameter direction. Although not shown, the belt layer 30 is composed of a plurality of steel cords embedded in the belt rubber. The belt rubber of the belt layer 30 is relatively easy to transmit electricity and has conductivity. As a result, the belt layer 30 has conductivity.

The belt reinforcement layer 40 is laminated on the outer side of the belt layer 30 in the tire diameter direction. The belt reinforcement layer 40 is located between the tread rubber 21 and the belt layer 30 in the tire diameter direction. The outer surface of the belt reinforcement layer 40 in the tire radial direction is connected to the inner surface of the tread under cushion 23 of the tread rubber 21 in the tire radial direction.

The belt reinforcement layer 40 is composed of, for example, a composite cord containing rubber and nylon wound multiple times around the outer periphery of the belt layer 30. One winding section of the composite cord constituting the belt reinforcement layer 40 is arranged with a gap 41 between each other along the tire width direction. Although not shown, in the gap 41 between one winding portion of the belt reinforcement layer 40, the tread under cushion 23 sandwiching the belt reinforcement layer 40 in the tire diameter direction and the belt layer 30 are aligned with each other. You are connected. The belt reinforcement layer 40 is relatively difficult to pass electricity through.

As shown in FIG. 2, the bead portion 13 is provided with a conductive rubber portion 80. The conductive rubber portion 80 is relatively easy to pass electricity through and has conductivity. The volume resistivity of the conductive rubber portion 80 is smaller than that of the carcass rubber 51a. The volume resistivity of the conductive rubber portion 80 is, for example, smaller than the volume resistivity of the first chafer portion 71 and the volume resistivity of the second chafer portion 29 . The volume resistivity of the conductive rubber portion 80 is different from that of other rubber materials constituting the bead portion 13, for example.

In addition, the volume resistivity of the conductive rubber portion 80 may be equal to the volume resistivity of the first chafer portion 71 and the volume resistivity of the second chafer portion 29, and the volume resistivity of the first chafer portion 71 may be equal to that of the second chafer portion 29. It may be greater than the volume resistivity and the volume resistivity of the second chafer portion 29.

The conductive rubber portion 80 is provided between the carcass ply 51 and the bead core 60. The conductive rubber portion 80 is disposed from the inside of the core coating portion 53, penetrating through the core coating portion 53, and extending to the outside of the core coating portion 53. The conductive rubber portion 80 is annular extending along the tire circumferential direction. The conductive rubber portion 80 has a first portion 81, a second portion 82, and a third portion 83.

The first portion 81 is located inside the bead core 60 in the tire diameter direction. That is, the first portion 81 is provided inside the tire radial direction rather than the outer end of the bead core 60 in the tire radial direction. As a result, at least a part of the conductive rubber portion 80 is provided inside the tire radial direction rather than the outer end of the bead core 60 in the tire radial direction. The first portion 81 extends in the tire width direction. The first portion 81 is disposed to penetrate the carcass layer 50 in the tire diameter direction. The outer end of the first portion 81 in the tire diameter direction is in contact with the bead core 60. The inner end of the first portion 81 in the tire diameter direction is connected to the first chafer portion 71 . More specifically, the inner end of the first portion 81 in the tire radial direction is connected to the radial coating portion 72 of the first chafer portion 71. As shown in FIG. 3 , the first portion 81 has a base (interposed portion) 84, a penetrating portion (embedded portion) 85, and a non-penetrating portion (embedded portion) 86.

The base 84 is laminated on the outer side of the carcass ply 51 in the tire diameter direction. A conductive portion 52 is buried in the base 84. As a result, the first portion 81 is connected to the conductive portion 52. In this embodiment, the base 84 corresponds to an intervening portion located between the bead core 60 and the carcass ply 51.

The penetrating portion 85 extends from the base 84 inward in the tire diameter direction. A plurality of penetrating portions 85 are provided, for example, along the tire circumferential direction. The penetrating portion 85 penetrates the portion of the carcass rubber 51a located between the ply cords 51b in the tire diameter direction. In this embodiment, the penetrating portion 85 divides the carcass rubber 51a in the tire circumferential direction. The inner end of the penetrating portion 85 in the tire radial direction is connected to the radial coating portion 72 of the first chafer portion 71. The dimension of the penetrating portion 85 in the tire radial direction is larger than the dimension of the base 84 in the tire radial direction. The penetrating portion 85 penetrates the carcass ply 51 from the other side surface to the one side surface. That is, the penetrating portion 85 penetrates the carcass ply 51 in the thickness direction. As a result, the conductive rubber portion 80 penetrates one surface and the other surface of the carcass ply 51.

In this embodiment, the penetrating portion 85 corresponds to a buried portion embedded in the carcass ply 51. More specifically, in the present embodiment, the penetrating portion 85 corresponds to the first embedded portion embedded in the portion of the carcass ply 51 located inside the bead core 60 in the tire radial direction. In this embodiment, the penetrating portion 85, which is a buried portion, is located between the ply cords 51b. In addition, in this specification, “the embedded portion is embedded in the carcass ply” includes the embedded portion being embedded in the carcass rubber of the carcass ply. In this embodiment, the penetration portion 85, which is an embedded portion, is embedded in the carcass rubber 51a.

The non-penetrating portion 86 extends from the base 84 inward in the tire diameter direction. The non-penetrating portion 86 is embedded in a portion of the carcass rubber 51a located between the ply cords 51b. The inner end of the non-penetrating portion 86 in the tire radial direction does not reach the radial covering portion 72. That is, the non-penetrating portion 86 does not penetrate the carcass rubber 51a.

As described above, the first portion 81 connects the conductive portion 52 and the first chafer portion 71 on the inner side of the bead core 60 in the tire diameter direction, so that the conductive rubber portion 80 is connected to the bead core ( 60), the carcass ply 51 is disposed penetrating in the tire radial direction and connects the conductive portion 52 and the chafer portion 70. Additionally, the conductive rubber portion 80 connects the conductive portion 52 and the chafer portion 70 by penetrating between the ply cords 51b adjacent to each other in the tire circumferential direction in the tire diameter direction. As a result, the conductive rubber portion 80 of the present embodiment makes one surface of the carcass ply 51 and the other surface electrically conductive.

In addition, in this specification, "the conductive rubber portion conducts electricity between one surface and the other surface of the carcass ply" means that the conductive rubber portion conducts electricity from one side in the thickness direction of the carcass ply to the other side in the thickness direction of the carcass ply. It is sufficient to make it possible, and there is no need for static electricity from the vehicle to flow on one surface and the other surface of the carcass ply. For example, in this embodiment, static electricity from the vehicle does not flow to the carcass ply 51 itself, but flows from the chafer portion 70 located on one side in the thickness direction of the carcass ply 51 to the conductive rubber portion. It flows through (80) to the conductive portion 52 located on the other side of the carcass ply 51 in the thickness direction.

As shown in FIG. 2, the second portion 82 is located outside the bead core 60 in the tire width direction. The second part 82 extends from the outer end of the first part 81 in the tire width direction outward in the tire diameter direction. More specifically, the second part 82 extends obliquely from the outer end of the first part 81 in the tire width direction, outward in the tire diameter direction, and inward in the tire width direction. The outer end of the second portion 82 in the tire radial direction is located outside the first chafer portion 71 in the tire radial direction. A conductive portion 52 is buried in the second portion 82. As a result, the second portion 82 is connected to the conductive portion 52.

The entire outer portion 82a in the tire diameter direction of the second portion 82 includes a portion of the core covering portion 53 extending in the tire diameter direction through the inside of the bead core 60 in the tire width direction. , It is located in the tire width direction between the portion of the core covering portion 53 that extends in the tire diameter direction through the outer side of the bead core 60 in the tire width direction. More specifically, the outer portion 82a is provided by lamination on the inner surface of the carcass ply 51 in the tire width direction at a portion of the carcass ply 51 that is bent outward in the tire diameter direction around the bead core 60.

The inner portion 82b of the second portion 82 in the tire diameter direction has a base (interposed portion) 82c and a penetrating portion (embedded portion) 82d. In this embodiment, the base 82c corresponds to an intervening portion located between the bead core 60 and the carcass ply 51. The base 82c is a portion of the inner portion 82b located inside the carcass ply 51 in the tire width direction. In this embodiment, the penetrating portion 82d corresponds to a buried portion embedded in the carcass ply 51. More specifically, the penetrating portion 82d corresponds to the second embedded portion embedded in the portion of the carcass ply 51 located outside the bead core 60 in the tire width direction. The penetrating portion 82d penetrates the portion of the carcass rubber 51a located between the ply cords 51b in the tire width direction.

By providing the base portion 82c and the penetrating portion 82d, the inner portion 82b of the second portion 82 in the tire diameter direction is disposed to penetrate the carcass layer 50 in the tire width direction. The inner end of the inner portion 82b in the tire width direction is in contact with the bead core 60. The outer end of the inner portion 82b in the tire width direction is connected to the first chafer portion 71. More specifically, the outer end of the inner portion 82b in the tire width direction is connected to the width direction covering portion 73 of the first chafer portion 71. The inner portion 82b, like the first portion 81 shown in FIG. 3, penetrates in the tire width direction between ply cords 51b adjacent to each other in the tire circumferential direction to form a conductive portion 52 and a chafer portion. (70) is being accessed.

The dimension of the inner portion 82b in the tire width direction is larger than the dimension of the outer portion 82a in the tire width direction. The dimension of the inner portion 82b located inside the carcass ply 51 in the tire width direction is smaller than the dimension of the outer portion 82a in the tire width direction. The size of the portion located inside the carcass ply 51 in the tire width direction of the inner portion 82b, that is, the base portion 82c, which is an intervening portion, in the tire width direction becomes smaller as it moves toward the inside of the tire diameter direction. . The tire radial boundary between the outer portion 82a and the inner portion 82b is disposed at substantially the same position as the tire radial outer end of the bead core 60 in the tire radial direction.

The third portion 83 is located inside the bead core 60 in the tire width direction. The third portion 83 extends from the inner end of the first portion 81 in the tire width direction outward in the tire diameter direction. The outer end of the third portion 83 in the tire radial direction is located outside the first chafer portion 71 in the tire radial direction. A conductive portion 52 is buried in the third portion 83. As a result, the third portion 83 is connected to the conductive portion 52.

The entire outer portion 83a in the tire diameter direction of the third portion 83 includes a portion of the core covering portion 53 extending in the tire diameter direction through the inside of the bead core 60 in the tire width direction; , It is located in the tire width direction between the portion of the core covering portion 53 that extends in the tire diameter direction through the outer side of the bead core 60 in the tire width direction. More specifically, the outer portion 83a is located on the outer surface in the tire width direction of the portion of the carcass ply 51 extending from the tread portion 11 to the inner side of the bead core 60 in the tire width direction. It is provided in a stacked manner.

The inner portion 83b of the third portion 83 in the tire diameter direction has a base (interposed portion) 83c and a penetrating portion (embedded portion) 83d. In this embodiment, the base 83c corresponds to an intervening portion located between the bead core 60 and the carcass ply 51. The base 83c is a portion of the inner portion 83b located outside the carcass ply 51 in the tire width direction. In this embodiment, the penetrating portion 83d corresponds to a buried portion embedded in the carcass ply 51. More specifically, the penetrating portion 83d corresponds to the second embedded portion embedded in the portion of the carcass ply 51 located inside the bead core 60 in the tire width direction. The penetrating portion 83d penetrates the portion of the carcass rubber 51a located between the ply cords 51b in the tire width direction.

By providing the base portion 83c and the penetrating portion 83d, the inner portion 83b of the third portion 83 in the tire diameter direction is disposed to penetrate the carcass layer 50 in the tire width direction. The outer end of the inner portion 83b in the tire width direction is in contact with the bead core 60. The inner end of the inner portion 83b in the tire width direction is connected to the first chafer portion 71. More specifically, the inner end of the inner portion 83b in the tire width direction is connected to the width direction covering portion 74 of the first chafer portion 71. Like the first part 81 shown in FIG. 3, the inner portion 83b penetrates in the tire width direction between ply cords 51b adjacent to each other in the tire circumferential direction to form a conductive portion 52 and a chafer portion ( 70) is being connected.

The dimension of the inner portion 83b in the tire width direction is larger than the dimension of the outer portion 83a in the tire width direction. The dimension of the inner portion 83b located outside the carcass ply 51 in the tire width direction is smaller than the dimension of the outer portion 83a in the tire width direction. The size of the portion of the inner portion 83b located outside the carcass ply 51 in the tire width direction, that is, the base portion 83c, which is an intervening portion, in the tire width direction becomes smaller as it moves toward the inside of the tire diameter direction. . The boundary portion of the outer portion 83a and the inner portion 83b in the tire radial direction is disposed at substantially the same position in the tire radial direction as the outer end of the bead core 60 in the tire radial direction.

As described above, the second portion 82 connects the conductive portion 52 and the first chafer portion 71 on the outside of the bead core 60 in the tire width direction, so that the conductive rubber portion 80 forms a bead core ( On the outside of 60) in the tire width direction, the carcass ply 51 is disposed to penetrate the tire width direction and connects the conductive portion 52 and the chafer portion 70. Additionally, the third portion 83 connects the conductive portion 52 and the first chafer portion 71 on the inner side of the bead core 60 in the tire width direction, so that the conductive rubber portion 80 is connected to the bead core 60. ) on the inner side of the tire width direction, the carcass ply 51 is disposed to penetrate the tire width direction, and the conductive portion 52 and the chafer portion 70 are connected. Additionally, the conductive rubber portion 80 connects the conductive portion 52 and the chafer portion 70 by penetrating between the ply cords 51b adjacent to each other in the tire circumferential direction in the tire width direction.

In this embodiment, the dimension of the conductive rubber portion 80 in the tire width direction increases toward the inside of the tire diameter direction. That is, the conductive rubber portion 80 has a large dimension in the tire width direction in the inner portion in the tire diameter direction.

As shown in FIG. 1, the tire 10 is provided with a conductive path CP that discharges static electricity from the vehicle from the rim on which the tire 10 is mounted to the ground. The conductive path CP is a path through which static electricity transmitted from the rim of the tire 10 passes, from the second chafer portion 29 to the first chafer portion 71, the conductive rubber portion 80, and the conductive portion. (52), the belt layer 30, the gap 41 of the belt reinforcement layer 40, the tread under cushion 23, and the antenna rubber 27 in this order, and extends to the tread tread portion 11a. . As a result, the vehicle's static electricity transmitted from the rim can be discharged from the tread tread portion 11a to the ground.

In addition, as shown in FIG. 2, in this embodiment, the conductive path CP from the first chafer portion 71 to the conductive portion 52 through the conductive rubber portion 80 has, for example, a static charge diameter of FIG. A path through which static electricity flows from the directional coating portion 72 through the first portion 81 to the conductive portion 52, and a path through which static electricity flows from the width direction coating portion 73 through the second portion 82 to the conductive portion 52. Includes the path.

Additionally, as described above, in the gap 41 of the belt reinforcement layer 40, the tread under cushion 23 and the belt layer 30 are connected to each other. Therefore, the static electricity flowing from the conductive portion 52 to the belt layer 30 flows from the gap 41 to the tread under cushion 23.

According to this embodiment, the conductive rubber portion 80 makes one surface of the carcass ply 51 and the other surface electrically conductive. Therefore, even when the conductivity of the carcass ply 51 is low, the conductive rubber portion 80 allows the static electricity of the vehicle to pass from one side in the thickness direction of the carcass ply 51 to the other side in the thickness direction. Accordingly, by reducing the amount of carbon contained in the carcass rubber 51a of the carcass ply 51, the rolling resistance of the tire 10 can be reduced, and the static electricity of the vehicle can be appropriately discharged to the ground.

Additionally, according to this embodiment, the conductive rubber portion 80 penetrates one surface and the other surface of the carcass ply 51. Specifically, in this embodiment, the penetrating portions 85, 82d, and 83d, which are buried portions of the conductive rubber portion 80, penetrate the carcass ply 51 in the thickness direction. Therefore, the static electricity from the vehicle flows through the conductive rubber portion 80 (through portions 85, 82d, 83d), thereby transferring the static electricity from the vehicle from one side in the thickness direction of the carcass ply 51 to the other side in the thickness direction. It can be easily passed to the side.

According to this embodiment, penetrating portions 85, 82d, and 83d as embedded portions of the conductive rubber portion 80 are embedded in the carcass ply 51. That is, a part of the conductive rubber portion 80 is embedded in the carcass ply 51. Therefore, in the portion of the carcass ply 51 where the conductive rubber portion 80 is embedded, electricity can be easily passed through the conductive rubber portion 80. As a result, even when the conductivity of the carcass ply 51 is low, static electricity from the vehicle can be passed through the carcass ply 51 through the conductive rubber portion 80. Accordingly, a tire 10 having a structure that facilitates discharge of static electricity from the vehicle to the ground, regardless of the conductivity of the carcass ply 51, is obtained. Therefore, by reducing the amount of carbon contained in the carcass rubber 51a of the carcass ply 51, the rolling resistance of the tire 10 can be reduced, and the static electricity of the vehicle can be appropriately discharged to the ground.

Additionally, according to this embodiment, a penetrating portion 85, which is a first embedded portion, is embedded in a portion of the carcass ply 51 located inside the bead core 60 in the tire radial direction. Therefore, it is easy to bring the portion of the carcass ply 51 into which the conductive rubber portion 80 is embedded into contact with the chafer portion 70. As a result, it is easy to allow static electricity from the vehicle transmitted from the rim to the chafer portion 70 to pass through the carcass ply 51 through the conductive rubber portion 80 (penetrating portion 85). Therefore, it is easy to more appropriately discharge static electricity from the vehicle to the ground. In this embodiment, the penetrating portion 85, which is the first embedded portion, is in contact with the radial covering portion 72.

Additionally, according to this embodiment, a penetrating portion 82d, which is a second embedded portion, is embedded in the portion of the carcass ply 51 located outside the bead core 60 in the tire width direction. Therefore, it is easy to bring the portion of the carcass ply 51 into which the conductive rubber portion 80 is embedded into contact with the width direction covering portion 73 of the first chafer portion 71. As a result, it is easy to allow static electricity from the vehicle transmitted from the rim to the chafer portion 70 to pass through the carcass ply 51 through the conductive rubber portion 80 (penetrating portion 82d). Therefore, it is easy to more appropriately discharge static electricity from the vehicle to the ground.

Additionally, according to this embodiment, a penetrating portion 83d, which is a second embedded portion, is embedded in the portion of the carcass ply 51 located inside the bead core 60 in the tire width direction. Therefore, it is easy to bring the portion of the carcass ply 51 into which the conductive rubber portion 80 is embedded into contact with the width direction covering portion 74 of the first chafer portion 71. As a result, static electricity from the vehicle transmitted from the rim to the chafer portion 70 is easily allowed to pass through the carcass ply 51 through the conductive rubber portion 80 (penetrating portion 83d). Therefore, it is easy to more appropriately discharge static electricity from the vehicle to the ground.

Additionally, according to this embodiment, the penetration portions 85, 82d, and 83d, which are embedded portions, are located between adjacent ply cords 51b in the tire circumferential direction. Therefore, it is easy to dispose of a part of the conductive rubber portion 80 by embedding it in the carcass ply 51. In addition, it is easy to arrange the penetrating portions 85, 82d, and 83d through the carcass ply 51, and the conductive portion 52 and the chafer portion 70 can be more suitably connected by the conductive rubber portion 80. Easy to access.

Additionally, according to this embodiment, at least a part of the conductive rubber portion 80 is provided inside the tire radial direction rather than the outer end of the bead core 60 in the tire radial direction. Therefore, it is easy for static electricity from the vehicle transmitted from the rim to the chafer portion 70 to pass through the carcass ply 51 through the conductive rubber portion 80.

In addition, according to this embodiment, a conductive portion 52 is provided that extends along the carcass ply 51 and is at least partially located between the carcass ply 51 and the bead core 60. Additionally, the conductive portion 52 is connected to the conductive rubber portion 80 through bases 84, 82c, and 83c. Therefore, static electricity transmitted to the conductive rubber portion 80 can be transmitted to the conductive portion 52. As a result, even when the volume specific resistance of the carcass rubber 51a in the carcass ply 51 is relatively large and the conductivity of the carcass ply 51 is low, the vehicle transmitted from the rim to the chafer portion 70 Static electricity from can be transferred to the conductive portion 52 through the conductive rubber portion 80. As a result, static electricity from the vehicle can be transmitted to the tread portion 11 through the conductive portion 52, and static electricity can be discharged from the tread tread portion 11a of the tread portion 11 to the ground. Therefore, it is easy to more appropriately discharge static electricity from the vehicle to the ground.

Additionally, according to this embodiment, the volume resistivity of the conductive portion 52 is smaller than that of the conductive rubber portion 80. Therefore, it is easy to make the volume specific resistance of the conductive portion 52 suitably small. As a result, static electricity can be properly applied to the conductive portion 52 that forms the relatively long conductive path CP from the bead portion 13 to the tread portion 11. Therefore, it is easier to discharge static electricity from the vehicle to the ground.

Additionally, according to this embodiment, the conductive portion 52 is a filamentous member containing metal. Therefore, it is easy to make the volume specific resistance of the conductive portion 52 more appropriately small, and it is easier for static electricity to flow from the bead portion 13 to the tread portion 11 through the conductive portion 52. As a result, it is easier to discharge static electricity from the vehicle to the ground. Additionally, according to this embodiment, a plurality of conductive portions 52 are provided at intervals along the tire circumferential direction. Therefore, the conductive path CP through which static electricity flows from the bead portion 13 to the tread portion 11 can be increased, and the conductive portion 52 allows static electricity to flow from the bead portion 13 to the tread portion 11. It is easier to shed than. As a result, it is easier to discharge static electricity from the vehicle to the ground.

Additionally, according to this embodiment, the conductive rubber portion 80 connects the conductive portion 52 and the first chafer portion 71. The first chafer portion 71 covers the portion provided in the bead portion 13 of the carcass ply 51 from the inside of the tire in the radial direction and from both sides in the tire width direction. Therefore, the conductive rubber portion 80 as described above is disposed on the inside of the bead core 60 in the tire diameter direction and on both sides of the tire width direction, penetrating the carcass ply 51, and the conductive portion 52 ) and the chafer portion 70 are easy to adopt. That is, as in the present embodiment, the radial coating portion 72 and the conductive portion 52 are connected by the first portion 81 of the conductive rubber portion 80, and the second portion of the conductive rubber portion 80 It is easy to connect the width direction coating portions 73 and 74 and the conductive portion 52 by (82) and the third portion (83).

Additionally, according to this embodiment, the conductive rubber portion 80 has bases 84, 82c, and 83c as intervening portions located between the bead core 60 and the carcass ply 51. Therefore, it is easy to connect the conductive rubber portion 80 to the conductive portion 52 through the bases 84, 82c, and 83c. As a result, static electricity can be appropriately transferred from the conductive rubber portion 80 to the conductive portion 52. Therefore, it is easier to discharge static electricity from the vehicle to the ground.

Additionally, according to this embodiment, the conductive rubber portion 80 has a large dimension in the tire width direction in the inner portion in the tire diameter direction. Therefore, the portion of the conductive rubber portion 80 connected to the chafer portion 70 at the inner end in the tire diameter direction can be enlarged in the tire width direction. As a result, it is easier to connect the conductive rubber portion 80 and the chafer portion 70 more appropriately, and it is easy for static electricity to flow from the chafer portion 70 to the conductive portion 52 through the conductive rubber portion 80. Therefore, it is easier to discharge static electricity from the vehicle to the ground.

Additionally, according to this embodiment, the carcass rubber 51a is relatively difficult to transmit electricity to. Therefore, it is difficult for static electricity from the vehicle to pass through the carcass ply 51. However, as described above, according to the present embodiment, the conductivity of the carcass ply 51 is not limited, and static electricity from the vehicle is easily discharged to the ground. In other words, the effect of easily discharging static electricity to the ground regardless of the conductivity of the carcass ply 51 described above is more effectively obtained in a configuration in which the carcass rubber 51a is relatively difficult to pass electricity through.

Furthermore, according to this embodiment, the conductive rubber portion 80 is disposed on the outer side of the bead core 60 in the tire width direction, penetrating the carcass ply 51 in the tire width direction, and the conductive portion 52 ) and the chafer part 70 are connected. Therefore, in addition to the connection between the conductive portion 52 and the chafer portion 70 on the inside of the bead core 60 in the tire diameter direction, the conductive rubber portion is also connected on the outside of the bead core 60 in the tire width direction. Through (80), the conductive portion 52 and the chafer portion 70 can be connected. As a result, the connection area between the chafer portion 70 and the conductive portion 52 through the conductive rubber portion 80 can be increased, and the static electricity from the chafer portion 70 is transmitted more than through the conductive rubber portion 80. It can flow to the conductive portion 52 as appropriate. Therefore, it is easier to discharge static electricity from the vehicle to the ground.

Furthermore, according to this embodiment, the conductive rubber portion 80 is disposed on the inner side of the bead core 60 in the tire width direction, penetrating the carcass ply 51 in the tire width direction, and the conductive portion 52 ) and the chafer part 70 are connected. Therefore, the conductive rubber portion 80 is disposed on the inside of the bead core 60 in the tire radial direction and on both sides of the tire width direction, penetrating the carcass ply 51, and is connected to the conductive portion 52 and the body. The purbu (70) is connected. As a result, the connection area between the chafer portion 70 and the conductive portion 52 through the conductive rubber portion 80 can be increased, and the static electricity from the chafer portion 70 is transmitted through the conductive rubber portion 80. , it can flow to the conductive portion 52 more appropriately. Therefore, it is easier to discharge static electricity from the vehicle to the ground.

In addition, the embodiment of the present invention is not limited to the above-described embodiment, and the following configuration may be adopted.

The conductive rubber portion is not particularly limited as long as it has an embedded portion embedded in the carcass ply and has conductivity. The conductive rubber portion does not need to be connected to the conductive portion. The conductive rubber portion does not need to be connected to the chafer portion. When the embedded portion is embedded in the carcass ply, the position provided is not particularly limited. The buried portion does not have to penetrate the carcass ply. The buried portion does not need to be exposed to the surface of the carcass layer. The buried portion does not need to be connected to the intervening portion. The intervening portion does not need to be provided.

The conductive rubber portion does not have to penetrate the carcass ply in the tire width direction. That is, for example, in the above-described embodiment, the conductive rubber portion 80 does not need to have the second portion 82 and the third portion 83. The shape of the conductive rubber portion is not particularly limited. The conductive rubber portion does not need to have a large dimension in the tire width direction in the inner portion in the tire diameter direction.

Additionally, the conductive rubber portion may be part of the carcass rubber in the carcass ply. In this case, the carcass rubber has a first rubber portion and a second rubber portion having a smaller volume resistivity than the first rubber portion. The second rubber portion is a portion corresponding to the conductive rubber portion. The first rubber part is the part of the carcass rubber other than the second rubber part. In this case as well, it is easy to discharge static electricity from the vehicle to the ground, regardless of the conductivity of the carcass ply, in the same manner as described above.

The conductive portion is not particularly limited as long as it extends along the carcass ply, at least part of it is located between the carcass ply and the bead core, and has conductivity. The conductive part does not need to contain metal. The conductive portion may be made of, for example, a conductive rubber. The conductive portion may not be a filamentous member, and may be a layered member laminated on the carcass ply. The volume specific resistance of the conductive portion may be the same as that of the conductive rubber portion or may be greater than the volume resistivity of the conductive rubber portion. There is no need to prepare a challenge section.

The chafer portion is not particularly limited as long as it has conductivity and covers at least part of the periphery of the carcass ply. For example, in the above-described embodiment, the first chafer portion 71 does not need to have either or both of the width direction covering portions 73 and 74. When the first chafer portion 71 does not have the width direction coating portion 73, for example, the first chafer portion 71 has a second body at the outer end of the radial coating portion 72 in the tire width direction. It is connected to Purbu (29). The first chafer portion and the second chafer portion may be integrally molded. The chafer section does not need to be provided.

The carcass layer may have two or more carcass plies. In this case, the conductive rubber portion penetrates a plurality of carcass plies in the tire diameter direction to connect the chafer portion and the conductive portion. The carcass layer may have an inner liner attached to the inner surface of the carcass ply.

The configuration of the tread portion is not particularly limited as long as static electricity can flow from the conductive portion extending to the tread portion to the tread tread portion.

The tire of the above-described embodiment may be used on any vehicle.

Additionally, each configuration described in this specification can be appropriately combined within a range that does not conflict with each other.

According to one aspect of the tire of the present invention, the conductive rubber portion makes one surface of the carcass ply and the other surface of the carcass ply conductive. Therefore, even when the conductivity of the carcass ply is low, the static electricity of the vehicle can be passed from one side in the thickness direction of the carcass ply to the other side in the thickness direction through the conductive rubber portion. Therefore, by reducing the amount of carbon contained in the carcass rubber of the carcass ply, the rolling resistance of the tire can be reduced, and the static electricity of the vehicle can be appropriately discharged to the ground.

The conductive rubber portion may be configured to penetrate one surface and the other surface of the at least one carcass ply.

According to this configuration, static electricity from the vehicle flows through the conductive rubber portion, allowing static electricity from the vehicle to easily pass from one side in the thickness direction of the carcass ply to the other side in the thickness direction.

The conductive rubber portion may be configured to have a buried portion embedded in the carcass ply.

According to this configuration, a portion of the conductive rubber portion is embedded in the carcass ply. Therefore, in the embedded portion of the carcass ply where the conductive rubber portion is embedded, electricity can easily be passed through the conductive rubber portion. As a result, even when the conductivity of the carcass ply is low, static electricity from the vehicle can be passed through the carcass ply through the conductive rubber portion. Accordingly, a tire can be obtained that has a structure that facilitates dissipation of static electricity from the vehicle to the ground, regardless of the conductivity of the carcass ply. Therefore, by reducing the amount of carbon contained in the carcass rubber of the carcass ply, the rolling resistance of the tire can be reduced, and the static electricity of the vehicle can be appropriately discharged to the ground.

The embedded portion may be configured to include a first embedded portion embedded in a portion of the carcass ply located inside the bead core in the tire radial direction.

According to this configuration, it is easy for the portion of the carcass ply in which the conductive rubber portion is embedded, that is, the portion in which the first embedded portion is embedded, to contact the chafer portion. As a result, it is easy to allow static electricity from the vehicle transmitted from the rim to the chafer portion to pass through the carcass ply through the first buried portion. Therefore, it is easy to more appropriately discharge static electricity from the vehicle to the ground.

The embedded portion may be configured to include a second embedded portion embedded in a portion of the carcass ply located on one side of the bead core in the tire width direction.

According to this configuration, it is easy for the portion of the carcass ply in which the conductive rubber portion is embedded, that is, the portion in which the second embedded portion is embedded, to contact the chafer portion. As a result, it is easy to allow static electricity from the vehicle transmitted from the rim to the chafer portion to pass through the carcass ply through the second buried portion. Therefore, it is easy to more appropriately discharge static electricity from the vehicle to the ground.

The embedded portion may be configured to penetrate the carcass ply in the thickness direction.

According to this configuration, static electricity from the vehicle flows through the conductive rubber portion (embedded portion), allowing static electricity from the vehicle to easily pass from one side in the thickness direction of the carcass ply to the other side in the thickness direction.

The carcass ply has carcass rubber and a plurality of ply cords embedded in the carcass rubber and arranged at intervals along the tire circumferential direction, and the embedded portion is located between the ply cords. You can do this.

According to this configuration, it is easy to arrange a part of the conductive rubber portion by embedding it in the carcass ply. Additionally, it is easy to arrange the buried portion through the carcass ply, and it is easy to more appropriately connect the conductive portion and the chafer portion with the conductive rubber portion.

At least a part of the conductive rubber portion may be provided inside the tire radial direction rather than an outer end of the bead core in the tire radial direction.

According to this configuration, it is easy to allow static electricity from the vehicle transmitted from the rim to the chafer portion to pass through the carcass ply through the conductive rubber portion.

It may be configured to include a conductive portion that extends along the carcass ply, at least a portion of which is located between the carcass ply and the bead core, and the conductive portion is connected to the conductive rubber portion.

According to this configuration, static electricity transmitted to the conductive rubber portion can be transmitted to the conductive portion. As a result, even when the volume specific resistance of the carcass rubber in the carcass ply is relatively large and the conductivity of the carcass ply is low, static electricity from the vehicle transmitted from the rim to the chafer portion can be transmitted to the conductive portion through the conductive rubber portion. You can. As a result, static electricity from the vehicle can be transmitted to the tread portion through the conductive portion, and static electricity can be discharged from the tread tread portion to the ground in the tread portion. Therefore, it is easy to more appropriately discharge static electricity from the vehicle to the ground.

The volume resistivity of the conductive portion may be smaller than that of the conductive rubber portion.

According to this configuration, it is easy to appropriately reduce the volume specific resistance of the conductive portion. As a result, static electricity can appropriately flow to the conductive portion that creates the relatively long conductive path CP from the bead portion to the tread portion. Therefore, it is easier to discharge static electricity from the vehicle to the ground.

The conductive portion may be configured to be a filamentous member containing metal.

According to this configuration, it is easy to reduce the volume specific resistance of the conductive portion more appropriately, and it is easier for static electricity to flow from the bead portion to the tread portion through the conductive portion. As a result, it is easier to discharge static electricity from the vehicle to the ground.

and a chafer portion that has conductivity and covers at least a portion of the periphery of the carcass ply, wherein the chafer portion extends a portion of the carcass ply provided in the bead portion from the inside of the tire in the radial direction and from both sides in the tire width direction. It has a first chafer portion covering a portion of the carcass ply provided in the bead portion, and a second chafer portion that covers the portion provided in the bead portion of the carcass ply from the outside in the tire width direction and is connected to the first chafer portion, wherein the conductive rubber portion is connected to the conductive portion. and the first chafer portion may be connected to each other.

According to this configuration, it is easy to adopt a configuration in which the conductive rubber portion is disposed inside the bead core in the tire radial direction and on both sides of the tire width direction, penetrating the carcass ply, and connecting the conductive portion and the chafer portion.

The conductive rubber portion may be configured to have a large dimension in the tire width direction in the inner portion in the tire radial direction.

According to this configuration, the portion connected to the chafer portion at the inner end of the conductive rubber portion in the tire diameter direction can be enlarged in the tire width direction. As a result, it is easier to connect the conductive rubber portion and the chafer portion more appropriately, and it is easy for static electricity to flow from the chafer portion to the conductive portion through the conductive rubber portion. Therefore, it is easier to discharge static electricity from the vehicle to the ground.

Another aspect of the tire of the present invention includes a bead core provided in a bead portion and a carcass ply that covers at least a portion of the periphery of the bead core, the carcass ply has carcass rubber, and the car Cuss rubber has a first rubber portion and a second rubber portion having a smaller volume resistivity than the first rubber portion.

According to another aspect of the tire of the present invention, as described above, a tire can be obtained that has a structure that facilitates dissipation of static electricity from the vehicle to the ground without being limited by the conductivity of the carcass ply. Therefore, by reducing the amount of carbon contained in the carcass rubber of the carcass ply, the rolling resistance of the tire can be reduced, and the static electricity of the vehicle can be appropriately discharged to the ground.

By applying the tire of the present application to the relevant field, it is possible to provide a tire having a structure that facilitates dissipation of static electricity from the vehicle to the ground, regardless of the conductivity of the carcass ply.

10: tires
13: Bead part
29: Second chafer section
51: Carcass fly
51a: Carcass rubber
51b: fly cord
52: Challenge section
60: bead core
70: Chaper part
71: first chafer part
80: Challenge Rubber Department
82d, 83d: Penetrating part (buried part, second buried part)
85: Penetrating part (buried part, first buried part)
86: Non-penetrating part (buried part)

Claims (14)

It is a tire having a tread part, a side wall part, and a bead part,
A bead core provided in the bead portion,
At least one carcass ply along at least a portion around the core axis of the bead core,
A conductive rubber portion provided between the carcass ply and the bead core.
Equipped with
The carcass ply is,
Carcass rubber,
It is embedded in the carcass rubber and has a plurality of ply cords arranged at intervals along the circumferential direction of the tire,
The tire wherein the conductive rubber portion penetrates between the ply cords adjacent to each other in the circumferential direction of the tire to conduct electricity between one surface and the other surface of the at least one carcass ply. delete According to paragraph 1,
A tire wherein the conductive rubber portion has a buried portion embedded in the carcass ply. According to paragraph 3,
The embedded portion includes a first embedded portion embedded in a portion of the carcass ply located inside the bead core in the tire radial direction. According to clause 3 or 4,
The tire wherein the embedded portion includes a second embedded portion embedded in a portion of the carcass ply located on one side of the bead core in the tire width direction. According to clause 3 or 4,
The tire wherein the buried portion penetrates the carcass ply in the thickness direction. According to clause 3 or 4,
The tire wherein the buried portion is located between the ply cords. According to any one of paragraphs 1, 3, and 4,
A tire, wherein at least a part of the conductive rubber portion is provided inside the tire radial direction rather than an outer end of the bead core in the tire radial direction. According to any one of paragraphs 1, 3, and 4,
A conductive portion extending along the carcass ply, at least a portion of which is located between the carcass ply and the bead core,
A tire wherein the conductive portion is connected to the conductive rubber portion. According to clause 9,
A tire wherein the volume resistivity of the conductive portion is smaller than the volume resistivity of the conductive rubber portion. According to clause 10,
A tire wherein the conductive portion is a filamentous member containing metal. According to clause 9,
It has conductivity and includes a chafer portion that covers at least a portion of the periphery of the carcass ply,
The chafer part,
A first chafer portion covering the portion of the carcass ply provided in the bead portion from the inside of the tire in the diametric direction and from both sides in the tire width direction;
A second chafer portion covers the portion of the carcass ply provided in the bead portion from the outside in the tire width direction and is connected to the first chafer portion.
With
A tire wherein the conductive rubber portion connects the conductive portion and the first chafer portion. According to any one of paragraphs 1, 3, and 4,
A tire in which the conductive rubber portion has a dimension in the tire width direction at an inner portion in the tire radial direction larger than a dimension in the tire width direction at an outer portion. It is a tire having a tread part, a side wall part, and a bead part,
A bead core provided in the bead portion,
Carcass ply covering at least a portion of the periphery of the bead core
Equipped with
The carcass ply is,
Carcass rubber,
It is embedded in the carcass rubber and has a plurality of ply cords arranged at intervals along the circumferential direction of the tire,
The carcass rubber is,
A first rubber portion,
A second rubber portion having a smaller volume specific resistance than the first rubber portion,
The tire wherein the second rubber portion penetrates between the ply cords adjacent to each other in the circumferential direction of the tire and causes one surface of the carcass ply to be connected to the other surface of the carcass ply.

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